Cooling-based systems are the most common, while
hygroscopic systems are showing promise. Hybrid systems combine
adsorption, refrigeration and condensation.
Air wells are another way to passively collect moisture.
Cooling condensation Condensing systems are the most common approach. They use a
compressor to circulate
refrigerant through a condenser and an evaporator coil to cool the surrounding air. Once the air reaches its
dew point, water condenses into the collector. A fan pushes filtered air over the coil. A purification/filtration system removes contaminants and reduces the risk posed by ambient microorganisms. The rate of water production depends on the ambient temperature, humidity, the volume of air passing over the coil, and the machine's cooling capacity. AWGs become more effective as relative humidity and air temperature increase. As a rule of thumb, cooling condensation AWGs do not work efficiently when the ambient temperature falls below or the relative humidity drops below 30%. The
Peltier effect of semiconducting materials offer an alternative condensation system in which one side of the semi-conducting material heats while the other side cools. In this approach, the air is sent over the cooling fins on the cool side, which lowers the air temperature. Solid-state semiconductors are convenient for portable units, but this is offset by low efficiency and high power consumption. Generation can be enhanced in low humidity conditions by using an
evaporative cooler with a
brackish water supply to increase humidity. Greenhouses are a special case because the interior air is hotter and more humid. Examples include the
seawater greenhouse in
Oman and the
IBTS Greenhouse. Dehumidifying
air conditioners produce non-potable water. The relatively cold (below the dewpoint) evaporator coil condenses water vapor from the processed air. When powered by coal-based electricity it has one of the worst
carbon footprints of any water source (exceeding
reverse osmosis seawater desalination by three
orders of magnitude) and demands more than four times as much water up the supply chain than it delivers to the user.
Hygroscopy Hygroscopic techniques pull water from the air via
absorption or
adsorption, which desiccate the air. Desiccants may be liquid ("wet") or solid. They need to be regenerated (typically thermally) to recover the water. The most efficient and sustainable method is to use an adsorption refrigerator powered by
solar thermal, which outperforms
photovoltaic-powered systems. Such systems can use waste heat, e.g. for pumping or for overnight operation, when humidity tends to rise. In 2024 a sorbent-based atmospheric water harvesting (SAWH) technology using a fin-array adsorption bed powered by high-density waste heat demonstrated 5.8 liters per kg of sorbent per day at 30% humidity via a 1 l adsorbent bed and commercial adsorbents.
Wet desiccants Examples of liquid
desiccants include
lithium chloride,
lithium bromide,
calcium chloride,
magnesium chloride,
potassium formate,
triethylene glycol, and [EMIM][OAc]. Concentrated
brine can serve as a desiccant. The brine absorbs water, which is then extracted and purified. Some versions produce 5 gallons of water per gallon of fuel. Concentrated brine, streamed down the outside of towers, absorbs water vapor. The brine then enters a chamber, under a partial
vacuum and is heated, releasing water vapor that is condensed and collected. As the condensed water is removed from the system using gravity, it creates a vacuum which lowers the brine's boiling point. The system can be powered by
passive solar energy.
Hydrogels can capture moisture (e.g. at night in a desert) to cool solar panels or produce fresh water. One application is to irrigate crops locating the hydrogel next to
solar panel integrated systems or beneath the panels.
Solid desiccants Silica gel and
zeolite desiccate pressurized air. One device consumes per liter of water. It uses a
zirconium/organic
metal-organic framework on a porous copper base, attached to a graphite substrate. The sun heats the graphite, releasing the water, which then cools the graphite.
Fuel cells A hydrogen
fuel cell car generates one liter of potable water for every 8 miles (12.87 kilometers) traveled by combining hydrogen with ambient oxygen.
Hydropanel Potable water can be generated by rooftop solar hydropanels using solar power and solar heat. == Energy ==